We show that the Casimir effect can emerge in microswimmer suspensions. In principle, two effects conspire
against the development of Casimir effects in swimmer suspensions. First, at low Reynolds number, the force
on any closed volume vanishes, but here the relevant effect is the drag by the flow produced by the swimmers,
which can be finite. Second, the fluid velocity and the pressure are linear on the swimmer force dipoles, and
averaging over the swimmer orientations would lead to a vanishing effect. However, being that the suspension is
a discrete system, the noise terms of the coarse-grained equations depend on the density, which itself fluctuates,
resulting in effective nonlinear dynamics. Applying the tools developed for other nonequilibrium systems to
general coarse-grained equations for swimmer suspensions, the Casimir drag is computed on immersed objects,
and it is found to depend on the correlation function between the rescaled density and dipolar density fields.
By introducing a model correlation function with medium-range order, explicit expressions are obtained for the
Casimir drag on a body.When the correlation length is much larger than the microscopic cutoff, the average drag
is independent of the correlation length, with a range that depends only on the size of the immersed bodies.
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This research is supported by Fondecyt Grant No. 1140778.
C.P.-R. acknowledges the support of a Becas Chile CONICYT
Scholarship No. 72140425.